Dies (Rheology)

A die is a solid piece of hardened steel or tungsten carbide that is finely machined into a cylindrical shape before a cylindrical hole (capillary) is bored through its center, normally by means of electro-erosion techniques. The term ‘capillary’ is sometimes used to indicate the whole die. Dies can be made of different materials such as stainless steel (Stavax) or nickel alloys (Hastelloy) for use with corrosive samples. The sample under test flows out through the capillary. Dies for rheology are used in melt flow instruments and capillary rheometers. They come in a range of different “geometries” to suit different applications and meet the requirements of different standards.

Dies are described by the length and diameter of the capillary, and by the shape of the capillary inlet. Dies are often described by their ‘length over diameter ratio’ or ‘L/D’ and entry angle: e.g. if the capillary length is 20 mm and the diameter is 1 mm, with an inlet consisting of a 90°-opening cone, it will be described as a die with 1-mm diameter capillary, L/D= 20, conical 90° inlet. A flat inlet corresponds to 180°. Special dies can be machined having a very short capillary, normally in the range of 0.25 mm: they are called ‘orifice dies’ or ‘zero-length dies’ and can be used for direct measurement of entrance pressure drop.

The standard die for melt flow tests has a capillary with a diameter of 2.095 mm and a length of 8 mm, with a flat inlet. Special methods call for longer dies, also with conical inlet (ASTM D3364 for tests on PVC).

Dies for capillary rheometers range in diameter from less than 0.5 mm to more than 2 mm, from ‘zero-length’ up to 40 mm or more in length. Inlet shape is normally flat or 90° conical.

Standards recommend for Bagley correction at least two different dies with same capillary diameter and different lengths, while other combinations are required for different applications (e.g. two dies with same L/D for Mooney wall slip evaluation).

References

ISO 11443: 2005 “Determination of the fluidity of plastics using capillary and slit-die rheometers”